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[1] H.Y. Kim, S. Miyazaki, gSeveral Issues in the Development of Ti–Nb-Based Shape Memory Alloysh, Shape Memory and Superelasticity, 2 (2016) 380-390.

[2] L. S. Wei, H.Y. Kim, T. Koyano, S. Miyazaki, gEffects of oxygen concentration and temperature on deformation behavior of Ti-Nb-Zr-Ta-O alloysh, Scripta Materialia, 123 (2016) 55-58.

[3] M. Tahara, T. Inamura, H.Y. Kim, S. Miyazaki, H. Hosoda, gRole of oxygen atoms in ƒ¿ martensite of Ti-20at.% Nb alloyh, Scripta Materialia 112 (2016), 15-18.

[4] Y. Namigata, Y. Hattori, M.I. Khan, H.Y. Kim, S. Miyazaki, gEnhancement of shape memory properties through precipitation hardening in a Ti-Rich Ti-Ni-Pd high temperature shape memory alloyh, Materials Transactions, 57 (2016) 241-249.

[5] S.H. Kayani, M.I. Khan, F.A. Khalid, H.Y. Kim, S. Miyazaki, gPrecipitation behavior of thermo-mechanically treated Ti50Ni20Au20Cu10 High-temperature shape-memory alloyh, Shape Memory and Superelasticity, 2 (2016) 29-36.

[6] T. Inamura, R. Shimizu, H.Y. Kim, S. Miyazaki, H. Hosoda, gOptimum rolling ratio for obtaining {001}<110> recrystallization texture in Ti-Nb-Al biomedical shape memory alloyh, Materials Science and Engineering C, 61 (2016) 499-505.

[7] K. Endoh, M. Tahara, T. Inamura, H.Y. Kim, S. Miyazaki, H. Hosoda, gEffect of Zr addition on mechanical and shape memory properties of Ti-5Mo-3Sn Alloysh, Journal of the Japan Institute of Metals, 80 (2016) 37-44.

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